A quantum mechanical polarizable force field for biomolecular interactions

Donchev, Alexander; Озрин, В. Д.; Subbotin, M.V.; Тарасов, В. И.

doi:10.1073/pnas.0502962102

Cited by 82 publications

(89 citation statements)

References 25 publications

(17 reference statements)

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“…14, except for the diffusion constant taken from ref. 15. As seen, the QMPFF2 classical MD results are close to the experimental values.…”

Section: Qmpff2supporting

confidence: 71%

“…5). The restraint potential provided by the spring is close to harmonic at small distances, but the stiffness becomes infinite as the distance approaches a limiting value, thus preventing the ''polarization catastrophe'' (15). For QMPFF1 the induction term is isotropic, whereas for QMPFF2 it is anisotropic (see Eq.…”

Section: Methodsmentioning

confidence: 99%

“…ref. 15 and Tables 4 and 5, which are published as supporting information on the PNAS web site. To accommodate the more refined functional forms of the QMPFF2 nonbonded interactions, each atom type requires eight parameters, and each general bond type requires five parameters (two parameters for symmetric bonds).…”

Section: Methodsmentioning

confidence: 99%

“…ref. 15 and Eqs. 6 and 7 in Supporting Text, which is published as supporting information on the PNAS web site.…”

Section: Methodsmentioning

confidence: 99%

“…QMPFF1 accurately simulates the interactions in many organic complexes (15). In this article we present the results of classical and PIMD simulations of liquid water by using a second, more refined version of the force field, QMPFF2.…”

mentioning

confidence: 99%

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Water properties from first principles: Simulations by a general-purpose quantum mechanical polarizable force field

Donchev¹,

Галкин²,

Illarionov³

et al. 2006

Proc. Natl. Acad. Sci. U.S.A.

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We have recently introduced a quantum mechanical polarizable force field (QMPFF) fitted solely to high-level quantum mechanical data for simulations of biomolecular systems. Here, we present an improved form of the force field, QMPFF2, and apply it to simulations of liquid water. The results of the simulations show excellent agreement with a variety of experimental thermodynamic and structural data, as good or better than that provided by specialized water potentials. In particular, QMPFF2 is the only ab initio force field to accurately reproduce the anomalous temperature dependence of water density to our knowledge. The ability of the same force field to successfully simulate the properties of both organic molecules and water suggests it will be useful for simulations of proteins and protein-ligand interactions in the aqueous environment.G eneral-purpose force fields, from Levitt's early protein potential (1) to modern models such as CHARMM, OPLS-AA, MMFF, and AMBER (2-5), which approximate molecular potentials by simple analytical formulas, are in wide use for computational studies of biological systems ranging from the simplest molecular clusters to large complexes involving proteins. In the latter case, the investigations encounter serious computational problems, primarily related to proper conformational sampling and adequate treatment of the long-range intermolecular interactions; however, with advancements in simulation methodologies and the increase in computer speed these difficulties are alleviated so the accuracy of the underlying models becomes the dominant factor.Protein and protein-ligand interactions usually take place in an aqueous environment, which contributes critically to their energetics, e.g., by hydrogen bonding and the hydrophobic effect. Hence, a force field should accurately reproduce the properties of both organic compounds and water if it is to be used for precise calculations of protein-ligand binding, as required for example in drug-design applications. Moreover, the quality of the applications of a force field to water can be considered as a criterion for the accuracy of the approach as a whole. Hence, it is disconcerting that no general-purpose force field has previously succeeded in accurately describing key properties of liquid water.On the other hand, impressive progress has been made in theoretical studies using specialized water potentials. Many of these potentials are empirical, i.e., they have been fitted to experimental data on the thermodynamics and kinetics of liquid water and in some cases ice. The most advanced of these models, such as the pairwise additive TIP5P (6) and polarizable (7-9) potentials, generally provide an accurate description of the most important properties of water and͞or ice. However, no one model is yet able to reproduce in detail the diversity of thermodynamic and kinetic experimental data on both gas and condensed phases under a range of conditions. Moreover, these empirical water potentials cannot be transferred to more general molecular systems ...

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“…14, except for the diffusion constant taken from ref. 15. As seen, the QMPFF2 classical MD results are close to the experimental values.…”

Section: Qmpff2supporting

confidence: 71%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

“…ref. 15 and Eqs. 6 and 7 in Supporting Text, which is published as supporting information on the PNAS web site.…”

Section: Methodsmentioning

confidence: 99%

mentioning

confidence: 99%

See 3 more Smart Citations

Water properties from first principles: Simulations by a general-purpose quantum mechanical polarizable force field

Donchev¹,

Галкин²,

Illarionov³

et al. 2006

Proc. Natl. Acad. Sci. U.S.A.

Self Cite

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Molecular Modeling of Nucleic Acid Structure: Electrostatics and Solvation

Bergonzo

Galindo‐Murillo

Cheatham

2013

CP Nucleic Acid Chemistry

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This unit presents an overview of computer simulation techniques as applied to nucleic acid systems, ranging from simple in vacuo molecular modeling techniques to more complete all-atom molecular dynamics treatments that include an explicit representation of the environment. The third in a series of four units, this unit focuses on critical issues in solvation and the treatment of electrostatics. UNITS 7.5 & 7.8 introduced the modeling of nucleic acid structure at the molecular level. This included a discussion of how to generate an initial model, how to evaluate the utility or reliability of a given model, and ultimately how to manipulate this model to better understand the structure, dynamics, and interactions. Subject to an appropriate representation of the energy, such as a specifically parameterized empirical force field, the techniques of minimization and Monte Carlo simulation, as well as molecular dynamics (MD) methods, were introduced as means to sample conformational space for a better understanding of the relevance of a given model. From this discussion, the major limitations with modeling, in general, were highlighted. These are the difficult issues in sampling conformational space effectively-the multiple minima or conformational sampling problems-and accurately representing the underlying energy of interaction. In order to provide a realistic model of the underlying energetics for nucleic acids in their native environments, it is crucial to include some representation of solvation (by water) and also to properly treat the electrostatic interactions. These are discussed in detail in this unit. SubjectNucleic Acid Chemistry; Nucleic Acid Structure and Folding; Structural Analysis of Biomolecules; Experimental Determination of Structure ELECTROSTATICS AND SOLVATIONAccurately modeling the structure and dynamics of nucleic acids with standard ab initio or empirical potentials presents special difficulties due to the highly charged phosphate backbone and the observation that nucleic acids are essentially always hydrated. Even under extremely dehydrating conditions, DNA still has very tightly associated water. To apply an accurate model, some representation of this structural and solvating water is likely necessary. Water has a structural role as both a donor and acceptor of hydrogen bonds, and Internet ResourcesAscona B-DNA Consortium website.

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ABEEM Polarizable Force Field

Zhao¹,

Yang²

2022

Conceptual Density Functional Theory

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A quantum mechanical polarizable force field for biomolecular interactions

Cited by 82 publications

References 25 publications

Water properties from first principles: Simulations by a general-purpose quantum mechanical polarizable force field

Water properties from first principles: Simulations by a general-purpose quantum mechanical polarizable force field

Molecular Modeling of Nucleic Acid Structure: Electrostatics and Solvation

ABEEM Polarizable Force Field

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